ALMA The Atacama Large Millimeter Array

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wnb-030516 Synthesis Imaging Workshop 1 ALMA The Atacama Large Millimeter Array

description

ALMA The Atacama Large Millimeter Array. ALMA site. 5 km altitude at the foot of the high Andes. ALMA telescopes (EU). ALMA telescopes (US). ALMA specifications. 64 antennas, at 5km height 12m diameter,  20 m, 0.6” in 9m/s wind arrays of 150m to 12km - PowerPoint PPT Presentation

Transcript of ALMA The Atacama Large Millimeter Array

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ALMAThe Atacama Large Millimeter Array

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ALMA site

5 km altitude at the foot of the high Andes

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ALMA telescopes (EU)

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ALMA telescopes (US)

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ALMA specifications

• 64 antennas, at 5km height

• 12m diameter, 20 m, 0.6” in 9m/s wind

• arrays of 150m to 12km

• 10 bands in 31-950 GHz + 183 GHz WVR. Initially:• 86-119 GHz

• 211-275 GHz

• 275-370 GHz

• 602-720 GHz

• 8 GHz , dual polarisation, 4096 channels/IF (Note: varying numbers mentioned throughout project)

• 650 M€

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ALMA specifications

• all bands online

• any 1 + 0.5 bands accessible

• filled (150m) to ring (12km) and log-spiral or ring

• data rate: 2M visibilities/s average (12M vis/s peak) (= 6Mb/s average; 60Mb/s must be sustainable)

•all data archived (raw + images)

• AC (Compact or Complementary)A (optional JP)• 6-10 antennas of 6-8m diameter in ring or hexagon for short spacings

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ALMA specifications

• ESO (with 5% E) and US (with 5% CA)

• ESO/US each half of capital cost

• No exchange of funds

• Project split in Project Teams, with leader in both parties: one of them the overall PT leader

• JP will probably join (they hope in 2004): politically difficult. They will contribute

• 4 12m telescopes

• 7m telescopes for ACA (with infrastructure)

• next generation correlator

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Sensitivity goals

0.661260850

0.51849650

0.10120345

2.771230

1.539140

4.42790

1.52035

/1@)()(

*

*

*

*

skmmJySJySGHz

At 50 deg elevation and best 25% weather for λ<1mm; best 75% for λ>1mm

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Other arrays

Comparison with other mm arrays

1.0

0.63 [0.5]

2.4

1.3

1.4

Cont. sens. (mJy)

Line sens. (mJy)

Max. Bsln (km)

BW (GHz)

PolFreq. range (GHz)

a

SSB Tsys@ 90 GHz

Mosaic Speed (nD)

Total Area (m2)

Array

7.93.00.2285-1100.42501101900ATCA (5*22m)

8.2 [6.7]

0.40.5180-115, 210-250

0.715075 [90]880 [1060]

IRAM PdB(5[6]*15m)

430.41.0185-116, 126-152, 213-237

0.6540060470NMA (6*10m)

230.2-0.4

1.0186-116, 210-270

0.725062510OVRO (6*10.4m)

231.50.8170-115, 210-270

0.715061290BIMA (10*6.1m)

Sensitivity estimates are for 1 hr integration at 90 GHz, all pols. combined.Line sensitivity is for a 10 km/s channel.

Actual sensitivity will depend on atmospheric phase.

(Courtesy Tony Wong)

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ALMA map

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ALMA local area

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ALMA topo

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ALMA barometer

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ALMA humidity

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Atmospheric transparency

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ALMA water vapour

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ALMA temperature

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ALMA wind direction

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ALMA wind speed

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ALMA bands

(courtesy Wolfgang Wild)

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Noise regimesT

empe

ratu

re

in

K 1

.

10

.

1

00.

10

00.

Frequency in GHz

0.01 0.1 1.0 10. 100. 1000.

SKA-loSKA-mid

SKA-hiALMA

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System noise source

(courtesy Wolfgang Wild)

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Receiver optics

(courtesy Wolfgang Wild)

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ALMA schedule

Proposed original schedule:• 2 prototype (US and EU) antennas in August 2002

• US started test April 2003; EU October 2003

• January 2002: Construction (Phase 2) start

•April 2003 decision on antennas (+ 1 year?)• 2006 interim operations• 2011 full science operations

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ALMA status

Decisions:• ESO (+E) July 2, 2002 • USA (+CA) July 13, 2003• JP Contract signed in April 2001 – withdrawn June 2002• First talks about work division for 3 partners held in Paris • For computing 3rd partner adds 12% to cost• JP still hopes to add extra bands; next correlator; ACA; 12m prototype: in 2004• 15 February 2003 Phase 2 contract signed US/EU for about 650 M€

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Field-of-view

Primary beam from 180” (30GHz) – 6” (900GHz)

HST SKA 6cm

ALMA

15 M

pc

at

z =

2SKA 20 cm

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ALMA mosaicing

Many objects to be observed by ALMA, such as nearby galaxies and molecular clouds in our own galaxy, will be diffuse and much larger than ALMA’s primary beam. Mosaicing will have to be done. However, mosaicing places stronger constraints on the antennas than single pointing interferometry.Why not build a 70~m single dish to observe these big sources? Mosaicing is faster than single dish observations, mainly because of the multiple synthesised beams which can be formed within each primary beam.

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Mosaicing limits

Pointing: Because the emission spans beyond a single primary beam in mosaicing, small antenna pointing errors can have a large effect on the observed flux of a feature which lies near the half power point of the beam. Pointing accuracy of about 1/25th of the beamwidth will permit mosaics of about 1000:1 dynamic range (linear with ν). Surface Accuracy: Surface errors will scatter radiation into the primary beam sidelobes, and unmodeled primary beam sidelobe structure will limit the quality of mosaic images. While surface accuracy of 1/16th of a wavelength only degrades the dish efficiency by a factor of 2 from Ruze losses, 1000:1 dynamic range mosaics will require surface accuracies of about 1/40th of a wavelength (quadratic with ν).

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Mosaicing limits

Getting Very Short Spacings: The homogeneous array concept requires that the antennas be fairly close together (ie, 1.3 times the dish diameter for zenith observations) to be able to measure spatial frequencies in the range of the dish diameter. However, the antennas can actually smack into each other if the separation is less than about 1.5 dish diameters (depending upon the design). To improve the short spacing capabilities (i.e. the large scale structure) the ACA has been proposed with about 10 antennas of about 7m diameter.

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Phase stability

Inhomogeneously distributed water vapour results in different electrical path lengths above the different antennas, or phase errors. The phase errors scatter flux, limiting the dynamic range,and also cause decorrelation, which artificially decreases the source amplitude. The initial calibration is planned with a 183GHz spectral line WVR (cf the ATCA 22GHz WVR).

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Calibration possibilities

The complete ALMA array, with 64 telescopes has about 2000 baselines, many more than any other existing telescope. This enables the use of algorithms different from used in today’s mm instruments. E.g.:•use of redundant and quasi-redundant baselines•use of parameterised models for the phase errors across telescope aperture•use of pointing correction model parameters

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ALMA

With JWST, ALMA and SKA in the second decade of this century the electro-magnetic spectrum from 1μm till 10m will be available to the next generation of astronomers with a resolution of about 0.02”, and sensitivities of about two orders of magnitude higher than today’s..